Metallic cover

ABSTRACT

A metallic cover includes a bottom base and four side walls perpendicularly extending from a periphery of the rectangular bottom base. The four side walls cooperatively define a cavity together with the rectangular bottom base. The bottom base and each of the side walls of the metallic cover are correspondingly connected at an edge. The side walls of the metallic cover are formed by cold forging, thus a thickness of each of the side walls of the metallic cover is greater than that of the bottom base.

CROSS-REFERENCE TO RELATED APPLICATION

The present application is a divisional application of U.S. patentapplication Ser. No. 12/012,298, filed on Feb. 1, 2008.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to metallic covers, and moreparticularly to a metallic cover used for electronic devices and amethod for making the metallic cover.

2. Discussion of the Related Art

Generally, a metallic cover has a more appealing appearance and a bettersurface feel than a plastic cover, thus metallic covers are popularlyused for electronic devices such as mobile phones.

Referring to FIG. 14, a typical metallic cover 10 is shown. The metalliccover 10 includes a rectangular bottom base 11, a first side wall 12, asecond side wall 13, a third side wall 14, and a fourth side wall 15.The side walls 12, 13, 14, 15 perpendicularly extend from a periphery ofthe rectangular bottom base 11. Each of the side walls 12, 13, 14, 15connects to its adjacent side walls, thus the side walls 12, 13, 14, 15cooperatively define a cavity (not labeled) for receiving electroniccomponents (not shown).

Each of the side walls 12, 13, 14, 15 and the bottom base 11 areconnected at an edge (not labeled). The edge is generally a rounded edgeso that the metallic cover 10 can easily be made by metal drawingmethod.

However, in order to obtain a different appearance, an edge of anothertypical cover for connecting the side walls and the bottom base may be abeveled edge instead of the rounded edge. Generally, it is practicallyimpossible to produce the beveled edge using the metal drawing method. Atypical method for making a metallic cover with a beveled edge includestwo following steps: drawing a metal sheet into a preformed cover;pressing the preformed cover into a metallic cover with a beveled edgeby a forming die. However, the edges of the metallic cover are prone tocracks, when using the above method, thus decreasing quality of themetallic covers.

In addition, in order to reduce the volume, size or weight of theseelectronic devices such as mobile phones, the described metallic coversare generally made by thin metal sheet. However, a thickness of the sidewalls of the metallic covers is the same as that of the bottom base ofthe metallic covers. As a result, the strength of the side walls of themetallic covers is relatively low. To enhance the strength of the sidewalls of a metallic cover, a thickness of each side wall of the metalliccover should be greater than that of the bottom base of the metalliccover. It is also practically impossible to produce an unequal-thicknessmetallic cover using the metal drawing method. The unequal-thicknessmetallic cover is generally made by a die-casting method. However, theappearance of the unequal-thickness metallic cover made by thedie-casting method is not good, thus the unequal-thickness metalliccover needs to be polished to improve the quality of the appearance ofthe unequal-thickness metallic cover.

At present, unequal-thickness metallic covers can also be manufacturedby computerized numerical control (CNC) milling machines. A firsttypical method for making an unequal-thickness metallic cover will nowbe described. A relatively thick raw metallic block is provided. The rawmetallic block has to go through several milling processes so as to geta preformed body. The preformed body is made into a metallic cover by aprocess of finish machining. The above method for makingunequal-thickness metallic covers takes a great deal of time, forexample, it needs more than ten hours for a process to make oneunequal-thickness metallic cover of a mobile phone. Because theunequal-thickness metallic cover goes through several milling processes,the efficiency of the described method is low, thereby increasing thecost of the unequal-thickness metallic covers.

Referring to FIG. 15, a metallic cover made of aluminum alloy, e.g., analuminum alloy of grade AL5052 using the above milling method shows ametallographic photograph of a portion of the side walls of the metalliccover under 23±5 Celsius degrees (° C.) and 40-80% relative humidity(RH) conditions. The internal structure of the metallic cover ismagnified by 200×. The metallographic structure of the metallic cover isrelatively incompact. A Vickers hardness of the metallic cover under23±5° C., 40-80% RH and 0.5 kilograms (kgs) is in a range from 68 to 70.

Therefore, a new metallic cover is desired in order to overcome theabove described shortcomings. A new method having high efficiency formaking such metallic cover is also needed.

SUMMARY

In one aspect, a metallic cover includes a bottom base and a side wallextending from the bottom base. The side wall is formed by cold forgingso that a thickness of the side wall is greater than that of the bottombase.

In another aspect, a method for making the metallic cover describedabove, includes: drawing a metallic sheet into a preformed cover havinga bottom base and a plurality of side walls, and the bottom base andeach of the sidewalls connected at a rounded edge; forging the preformedcover by a first forming die to thicken the side walls, and a firstslanted pressing surface formed on an end of each of the side walls;forging the preformed cover by a second forming die to further thickenthe side walls, and a second slanted pressing surface intersecting withthe first slanted pressing surface formed on the end of each of the sidewalls, and the rounded edge of the preformed cover pressed into abeveled edge; and machining the end of each of the side walls of thepreformed metallic cover so that the preformed metallic cover is madeinto the metallic cover.

Other novel features and advantages will become more apparent from thefollowing detailed description, when taken in conjunction with theaccompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The components in the drawings are not necessarily drawn to scale, theemphasis instead being placed upon clearly illustrating principles ofthe present metallic cover and method for making the same. Moreover, inthe drawings, like reference numerals designate corresponding partsthroughout several views, and all the views are schematic.

FIG. 1 is an isometric view of a metallic cover in accordance with apreferred embodiment of the present invention.

FIG. 2 is a partial, cross-sectional view of an edge of the metalliccover of FIG. 1.

FIG. 3 is a metallographic photograph of part of the edge of themetallic cover magnified by 200×.

FIG. 4 is an isometric view of a preformed metallic cover formed in amethod for making the metallic cover of FIG. 1.

FIG. 5 is a cross-sectional view of a first forming die used forpressing the preformed metallic cover of FIG. 4.

FIG. 6 is an enlarged, side cross-sectional view of a punch of the firstforming die of FIG. 5.

FIG. 7 is a partial, cross-sectional view of the first forming die whichis pressing the preformed metallic cover of FIG. 4.

FIG. 8 is a partial, cross-sectional view of the preformed metalliccover after being pressed by the first forming die of FIG. 5.

FIG. 9 is a cross-sectional view of a second forming die used forfurther pressing the preformed metallic cover which has been pressed bythe first forming die of FIG. 5.

FIG. 10 is an enlarged, side cross-sectional view of a punch of thesecond forming die of FIG. 9.

FIG. 11 is a partial, cross-sectional view of the second forming diewhich is pressing the preformed metallic cover which has been pressed bythe first forming die.

FIG. 12 is a partial, cross-sectional view of the preformed metalliccover after being pressed by the second forming die of FIG. 9.

FIG. 13 is a partial, cross-sectional view of a third finish machiningdie for making the preformed metallic cover which pressed by the secondforming die of FIG. 9 into the metallic cover of FIG. 1.

FIG. 14 is an isometric view of a conventional metallic cover.

FIG. 15 is a metallographic photograph of part of the conventionalmetallic cover magnified by 200×.

DETAILED DESCRIPTION OF THE EMBODIMENTS

Reference will now be made to the drawings to describe preferredembodiments of the present metallic cover and method in detail.

Referring to FIGS. 1 and 2, a metallic cover 20 according to a preferredembodiment is shown. In the illustrated embodiment, the metallic cover20 is used as a cover for a mobile phone. The metallic cover 20 includesa rectangular bottom base 21, a first side wall 22, a second side wall23, a third side wall 24, and a fourth side wall 25. The side walls 22,23, 24, 25 perpendicularly extend from a periphery of the rectangularbottom base 21. The side walls 22, 23, 24, 25 cooperatively define acavity (not labeled). The bottom base 21 and each of the side walls 22,23, 24, 25 are correspondingly connected at an edge 26. The side walls22, 23, 24, 25 of the metallic cover 20 are formed by cold forging, thusa thickness of each of the side walls 22, 23, 24, 25 of the metalliccover 20 is greater than that of the bottom base 21 of the metalliccover 20.

In the described embodiment, b represents a thickness of the bottom base21, t represents a thickness of each of the side walls 22, 23, 24, 25,and h represents a height of each of the side walls 22, 23, 24, 25. Theratio between t and b (t/b) is preferably in a range from about 1 toabout 3, and the ratio between h and b (h/b) is preferably in a rangefrom about 1 to about 2.5. The metallic cover 20 is preferably made ofaluminum alloy. The edge 26 is a beveled edge formed by cold forging.The angle formed between an outer surface of the bottom base 21 and anouter surface of each of the sidewalls 22, 23, 24, 25 at the edge 26 isin a range from about 90 degrees to about 135 degrees.

It should be pointed out that, the bottom base 21 can also be othershapes such as triangular, pentagonal, and hexagonal. The edge 26 is notlimited to a beveled edge, the edge can also be other shapes, that is,not beveled, formed by cold forging.

Referring to FIG. 3, the metallic cover 20 made of aluminum alloy, e.g.,an aluminum alloy of grade 5052-0 using cold forging method shows ametallographic photograph of a portion of the metallic cover under 23±5°C. and 40-80% relative humidity (RH) conditions. The metallographicphotograph of the metallic cover is magnified by 200×. Themetallographic structure of the metallic cover is relatively compact. AVickers hardness of the metallic cover 20 under 23±5° C., 40-80% RH and0.5 kilograms (kgs) is in a range from 71 to 75. Therefore, the Vickershardness of the metallic cover 20 formed by cold forging is greater thanthe Vickers hardness of a metallic cover which is formed by millingmethod.

Referring to FIGS. 4 through 13, an exemplary method for making themetallic cover 20 will now be described. The method for making themetallic cover includes the following main steps: a drawing process; afirst cold forging process; a second cold forging process; and a finishmachining process.

In the drawing process, a metallic sheet is drawn into a preformedmetallic cover 30. In the illustrated embodiment, the metallic sheetused for making the preformed metallic cover 30 is preferably made ofaluminum alloys such as 5052-O aluminum alloy. The preformed cover 30includes a bottom base 31 and a plurality of side walls 32. The sidewalls 32 cooperatively define a cavity (not labeled) for receivingelectronic components (not shown). The bottom base 31 and each of thesidewalls 32 are connected at a rounded edge 33.

In the first cold forging process, the preformed cover 30 is forged by afirst forming die 200 to flatten the side walls 32, thereby thickening(widening) the side walls 32, and to form a first slanted pressedsurface 321 (see FIG. 8) on an end of each of the side walls 32.

Referring to FIGS. 5 through 8, the first forming die 200 includes anupper die 210, a lower die 220, a pressing member 230, a punch 240, afirst resilient member 250, and a second resilient member 260. The lowerdie 220 and the pressing member 230 are disposed adjacent to and onopposite sides of the punch 240 correspondingly. The punch 240, thelower die 220, and the pressing member 230 cooperatively define amolding groove 270 for receiving the side walls 32 of the preformedmetallic cover 30. A thickness of the molding groove 270 is greater thanthat of each of the side walls 32 of the preformed metallic cover 30.The upper die 210 is disposed above the lower die 220, the pressingmember 230, and the punch 240. The first resilient member 250 and thesecond resilient member 260 are both springs. The first resilient member250 is disposed below the lower die 220. The second resilient member 260is disposed below the pressing member 230. The upper die 210 includes aworking surface 2101 formed on a bottom surface for pressing the bottombase 31 of the preformed metallic cover 30. The lower die 220 includes amounting surface 2201 formed on a top surface for mounting the preformedmetallic cover 30. The pressing member 230 includes a side surface 2301and an upper surface 2302 perpendicular to each other. An extendingportion 2303 is formed on the side surface 2301 adjacent to the uppersurface 2302. The extending portion 2303 includes a pressing surface2304 for pushing against the side walls 32 of the preformed cover 30.The pressing surface 2304 is perpendicular to the working surface of theupper die 220, and is parallel to the side surface 2301.

The punch 240 includes a punching portion 2401 and a restricting portion2402 that connects to the punching portion 2401. The punching portion2401 includes a first side surface 2404, a second side surface 2405, anda slanted working surface 2406. The first side surface 2404 is parallelto the second side surface 2405, and the first side surface 2404 and thesecond side surface 2405 are on opposite sides of the punching portion2401 correspondingly. d₁ represents a distance between the first sidesurface 2404 and the second side surface 2405, and t represents thefinal thickness of the sidewall of the metallic cover. The distance d₁should be in a range from 0.7 t to 0.9 t. The distance d₁ is preferablyin a range from 0.8 t to 0.85 t. An edge of the slanted working surface2406 connects the first side surface 2404 and an opposite edge of theslanted working surface 2406 connects the second side surface 2405. Theedge of the slanted working surface 2406 adjacent to the first sidesurface 2404 is configured to be higher than the opposite edge of theslanted working surface 2406 adjacent to the second side surface 2405.In other words, the slanted working surface 2406 slants towards thefirst side surface 2404. An angle β₁ defined by the slanted workingsurface 2406 relative to the first side surface 2404 should be in arange from about 45 degrees to about 70 degrees. The angle β₁ ispreferably in a range from about 60 degrees to about 65 degrees. Therestricting portion 2402 includes a positioning surface 2403 forrestricting the motion range of the pressing member 230.

Before the first cold forging process, a distance between the uppersurface 2302 of the pressing member 230 and the mounting surface 2201 ofthe lower die 220 is greater than the thickness of the bottom base 31 ofthe preformed metallic cover 30. The pressing surface 2304 of theextending portion 2303 of the pressing member 230 abuts the second sidesurface 2405 of the punching portion 2401 of the punch 240. The sidesurface 2301 of the pressing member 230 abuts the restricting portion2402 of the punch 240. A lower end of the extending portion 2303 of thepressing member 230 is set a predetermined distance away from thepositioning surface 2403 of the restricting portion 2402 of the punch240. The preformed metallic cover 30 is placed on the lower die 220 andthe side walls 32 of the preformed metallic cover are received in themolding groove 270.

During the first cold forging process, the upper surface 2302 of thepressing member 230 and the bottom base 31 of the preformed metalliccover 30 are pressed by the upper die 210. When the lower die 220 andthe pressing member 230 are pressed, the first resilient member 250 andthe second resilient member 260 becomes compressed. When the lower die220 and the pressing member 230 are pressed, the side walls 32 of thepreformed metallic cover 30 received in the molding groove 270presses/pushes against the slanted working surface 2406 of the punch240; material of the side walls 32 displaces (molds) into the moldinggroove 270. When the pressing member 230 is pressed until the extendingportion 2303 of the pressing member 230 abuts the positioning surface2403 of the restricting portion 2402 of the punch 240, the lower die 220and the pressing member 230 stop moving. In the first cold forgingprocess, material of the side walls 32 of the preformed metallic cover30 flattens out into the molding groove 270, thus the side walls 32 ofthe preformed metallic cover 30 become thicker (wider) than the bottombase 31. The rounded edge 33 of the preformed cover 30 is pressed into asubstantially beveled edge.

In the second cold forging process, the preformed cover 30 is forged bya second forming die 300 to flatten the side walls 32, thereby furtherthickening (widening) the side walls 32, and to form a second slantedpressing surface 322 intersecting with the first slanted pressingsurface 321 on the end of each of the side walls 32. The rounded edge 33of the preformed cover 30 is pressed into the beveled edge 26.

Referring to FIGS. 9 through 12, the second forming die 300 includes anupper die 310, a lower die 320, a pressing member 330, a punch 340, afirst resilient member 350, and a second resilient member 360. Theprinciple of the second forming die 300 is similar to the first formingdie 200. However, the punch 340 is different from the punch 240 of thefirst forming die 200. The punch 340 will now be described in detail asfollows.

The punch 340 includes a punching portion 3401 and a restricting portion3402 connecting to the punching portion 3401. The punching portion 3401includes a first side surface 3404, a second side surface 3405, and aslanted working surface 3406. The first side surface 3404 is parallel tothe second side surface 3405, first side surface 3404 and the secondside surface 3405 are on opposite sides of the punching portion 3401correspondingly. A distance d₂ between the first side surface 3404 andthe second side surface 3405 equals to the thickness t of the sidewallof the metallic cover to be formed. An edge of the slanted workingsurface 3406 connects the first side surface 3404 and an opposite edgeof the slanted working surface 3406 connects the second side surface3405. The opposite edge of the slanted working surface 3406 adjacent tothe second side surface 3405 is configured to be higher than the edge ofthe slanted working surface 3406 adjacent to the first side surface3404. An angle β₂ defined by the slanted working surface 3406 relativeto the first side surface 3404 should be in a range from about 45degrees to about 70 degrees. The angle β₂ is preferably in a range fromabout 60 degrees to about 65 degrees. The restricting portion 3402includes a positioning surface 3403 for restricting the motion range ofthe pressing member 330. The punch 340, the lower die 320, and thepressing member 330 cooperatively define a molding groove 370 forreceiving the side walls 32 of the preformed metallic cover 30. Athickness of the molding groove 370 is greater than the thickness of theside walls 32 of the preformed metallic cover 30.

In the second cold forging process, the pressing member 330 and thebottom base 31 of the preformed metallic cover 30 is pressed by theupper die 310. When the lower die 320 and the pressing member 330 arepressed, the side walls 32 of the preformed metallic cover 30 receivedin the molding groove 370 presses/pushes against the slanted workingsurface 3406 of the punch 340; material of the side walls 32 displaces(molds) into the molding groove 370. When the extending portion 3303 ofthe pressing member 230 abuts the positioning surface 3403 of therestricting portion 3402 of the punch 340, the lower die 320 and thepressing member 330 stop moving. In the second cold forging process,material of the side walls 32 of the preformed metallic cover 30flattens out into the molding groove 370, thus the side walls 32 of thepreformed metallic cover 30 become thicker than the bottom base 31 andthe rounded edge 33 of the preformed cover 30 is pressed into bevelededge.

In the finish machining process, each of the side walls 32 of thepreformed metallic cover 30 is machined to a predetermined shape by amachining tool such as a milling machine, and thereby forming themetallic cover 20. In the described embodiment, the first slantedpressing surface 321 and the second slanted pressing surface 322 of eachof the side walls 32 are cut off and a flat surface is formed on theside walls 32.

In an alternative embodiment, referring to FIG. 13, in order to furtherimproving the surface appearance of the preformed metallic cover 30, aprecision machining process is applied between the second cold forgingprocess and the finish machining process. In the precision machiningprocess, the sidewalls 32 of the preformed metallic cover 30 areprocessed by a precision forming die 400. The precision forming die 400includes an upper die 401, a lower die 402, and a pressing plate 403. Inuse, the preformed metallic cover 30 is fixed on the lower die 402 bythe pressing plate 403, and the side walls of the preformed metalliccover 30 extend out of the lower die 402. When the upper die 401 movestowards the lower die 402, a part of the side walls 32 of the preformedmetallic cover 30 is cut off, thus the surface appearance the side walls32 is improved.

It is believed that the present embodiments and their advantages will beunderstood from the foregoing description, and it will be apparent thatvarious changes may be made thereto without departing from the spiritand scope of the invention or sacrificing all of its materialadvantages, the examples hereinbefore described merely being preferredor exemplary embodiments of the invention.

1. A metallic cover, comprising: a bottom base; and at least one side wall extending from the bottom base; wherein the at least one side wall is formed by cold forging so that a thickness of the at least one side wall is greater than that of the bottom base.
 2. The metallic cover as claimed in claim 1, wherein the bottom base and the at least one side wall are connected at an edge, and the edge is a beveled edge.
 3. The metallic cover as claimed in claim 2, wherein an angle defined by an outer surface of the bottom base relative to the at least one sidewall at the edge is in a range from 90 degrees to 135 degrees.
 4. The metallic cover as claimed in claim 2, wherein the metallic cover is made of aluminum alloy.
 5. The metallic cover as claimed in claim 1, wherein a ratio of a thickness of the at least one side wall with respect to a thickness of the bottom base is in a range from 1 to 3, and a ratio of a height of the at least one side wall with respect to the thickness of the bottom base is in a range from 1 to 2.5.
 6. The metallic cover as claimed in claim 1, wherein the bottom base is rectangular, the metallic cover comprises four side walls, and the side walls perpendicularly extend from a periphery of the rectangular bottom base.
 7. The metallic cover as claimed in claim 6, wherein the bottom base and each of the side walls are connected at an edge, and the edge is a beveled edge.
 8. The metallic cover as claimed in claim 7, wherein the metallic cover is made of aluminum alloy, and an angle defined by an outer surface of the bottom base relative to the sidewalls at the edge is in a range from 90 degrees to 135 degrees.
 9. The metallic cover as claimed in claim 8, wherein a ratio of a thickness of the side walls with respect to a thickness of the bottom base is in a range from 1 to 3, and a ratio of a height of the side walls with respect to the thickness of the bottom base is in a range from 1 to 2.5.
 10. A metallic cover, comprising: a rectangular bottom base; and four side walls perpendicularly extending from a periphery of the rectangular bottom base, and cooperatively defining a cavity together with the rectangular bottom base; wherein the bottom base and each of the side walls of the metallic cover are correspondingly connected at an edge, and the side walls of the metallic cover are formed by cold forging, thus a thickness of each of the side walls of the metallic cover is greater than that of the bottom base.
 11. The metallic cover as claimed in claim 1, wherein a ratio of a thickness of each of the side walls with respect to a thickness of the bottom base is in a range from 1 to 3, and a ratio of a height of each of the side walls with respect to the thickness of the bottom base is in a range from 1 to 2.5.
 12. The metallic cover as claimed in claim 12, wherein the metallic cover is made of aluminum alloy, and the edge is a beveled edge formed by cold forging.
 13. The metallic cover as claimed in claim 13, wherein an angle defined by an outer surface of the bottom base relative to the sidewalls at the edge is in a range from 90 degrees to 135 degrees. 